src/cmd/compile/internal/ssa/fuse.go - go - Git at Google

 // Copyright 2015 The Go Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style
 // license that can be found in the LICENSE file.

 package ssa

 import (
 	"cmd/internal/src"
 )

 // fuseEarly runs fuse(f, fuseTypePlain|fuseTypeIntInRange).
 func fuseEarly(f *Func) { fuse(f, fuseTypePlain|fuseTypeIntInRange) }

 // fuseLate runs fuse(f, fuseTypePlain|fuseTypeIf).
 func fuseLate(f *Func) { fuse(f, fuseTypePlain|fuseTypeIf) }

 type fuseType uint8

 const (
 	fuseTypePlain fuseType = 1 << iota
 	fuseTypeIf
 	fuseTypeIntInRange
 	fuseTypeShortCircuit
 )

 // fuse simplifies control flow by joining basic blocks.
 func fuse(f *Func, typ fuseType) {
 	for changed := true; changed; {
 		changed = false
 		// Fuse from end to beginning, to avoid quadratic behavior in fuseBlockPlain. See issue 13554.
 		for i := len(f.Blocks) - 1; i >= 0; i-- {
 			b := f.Blocks[i]
 			if typ&fuseTypeIf != 0 {
 				changed = fuseBlockIf(b) || changed
 			}
 			if typ&fuseTypeIntInRange != 0 {
 				changed = fuseIntegerComparisons(b) || changed
 			}
 			if typ&fuseTypePlain != 0 {
 				changed = fuseBlockPlain(b) || changed
 			}
 			if typ&fuseTypeShortCircuit != 0 {
 				changed = shortcircuitBlock(b) || changed
 			}
 		}
 		if changed {
 			f.invalidateCFG()
 		}
 	}
 }

 // fuseBlockIf handles the following cases where s0 and s1 are empty blocks.
 //
 //   b        b        b      b
 //  / \      | \      / |    | |
 // s0  s1    |  s1   s0 |    | |
 //  \ /      | /      \ |    | |
 //   ss      ss        ss     ss
 //
 // If all Phi ops in ss have identical variables for slots corresponding to
 // s0, s1 and b then the branch can be dropped.
 // This optimization often comes up in switch statements with multiple
 // expressions in a case clause:
 //   switch n {
 //     case 1,2,3: return 4
 //   }
 // TODO: If ss doesn't contain any OpPhis, are s0 and s1 dead code anyway.
 func fuseBlockIf(b *Block) bool {
 	if b.Kind != BlockIf {
 		return false
 	}

 	var ss0, ss1 *Block
 	s0 := b.Succs[0].b
 	i0 := b.Succs[0].i
 	if s0.Kind != BlockPlain || len(s0.Preds) != 1 || !isEmpty(s0) {
 		s0, ss0 = b, s0
 	} else {
 		ss0 = s0.Succs[0].b
 		i0 = s0.Succs[0].i
 	}
 	s1 := b.Succs[1].b
 	i1 := b.Succs[1].i
 	if s1.Kind != BlockPlain || len(s1.Preds) != 1 || !isEmpty(s1) {
 		s1, ss1 = b, s1
 	} else {
 		ss1 = s1.Succs[0].b
 		i1 = s1.Succs[0].i
 	}

 	if ss0 != ss1 {
 		return false
 	}
 	ss := ss0

 	// s0 and s1 are equal with b if the corresponding block is missing
 	// (2nd, 3rd and 4th case in the figure).

 	for _, v := range ss.Values {
 		if v.Op == OpPhi && v.Uses > 0 && v.Args[i0] != v.Args[i1] {
 			return false
 		}
 	}

 	// Now we have two of following b->ss, b->s0->ss and b->s1->ss,
 	// with s0 and s1 empty if exist.
 	// We can replace it with b->ss without if all OpPhis in ss
 	// have identical predecessors (verified above).
 	// No critical edge is introduced because b will have one successor.
 	if s0 != b && s1 != b {
 		// Replace edge b->s0->ss with b->ss.
 		// We need to keep a slot for Phis corresponding to b.
 		b.Succs[0] = Edge{ss, i0}
 		ss.Preds[i0] = Edge{b, 0}
 		b.removeEdge(1)
 		s1.removeEdge(0)
 	} else if s0 != b {
 		b.removeEdge(0)
 		s0.removeEdge(0)
 	} else if s1 != b {
 		b.removeEdge(1)
 		s1.removeEdge(0)
 	} else {
 		b.removeEdge(1)
 	}
 	b.Kind = BlockPlain
 	b.Likely = BranchUnknown
 	b.ResetControls()

 	// Trash the empty blocks s0 and s1.
 	blocks := [...]*Block{s0, s1}
 	for _, s := range &blocks {
 		if s == b {
 			continue
 		}
 		// Move any (dead) values in s0 or s1 to b,
 		// where they will be eliminated by the next deadcode pass.
 		for _, v := range s.Values {
 			v.Block = b
 		}
 		b.Values = append(b.Values, s.Values...)
 		// Clear s.
 		s.Kind = BlockInvalid
 		s.Values = nil
 		s.Succs = nil
 		s.Preds = nil
 	}
 	return true
 }

 // isEmpty reports whether b contains any live values.
 // There may be false positives.
 func isEmpty(b *Block) bool {
 	for _, v := range b.Values {
 		if v.Uses > 0 || v.Op.IsCall() || v.Op.HasSideEffects() || v.Type.IsVoid() {
 			return false
 		}
 	}
 	return true
 }

 func fuseBlockPlain(b *Block) bool {
 	if b.Kind != BlockPlain {
 		return false
 	}

 	c := b.Succs[0].b
 	if len(c.Preds) != 1 {
 		return false
 	}

 	// If a block happened to end in a statement marker,
 	// try to preserve it.
 	if b.Pos.IsStmt() == src.PosIsStmt {
 		l := b.Pos.Line()
 		for _, v := range c.Values {
 			if v.Pos.IsStmt() == src.PosNotStmt {
 				continue
 			}
 			if l == v.Pos.Line() {
 				v.Pos = v.Pos.WithIsStmt()
 				l = 0
 				break
 			}
 		}
 		if l != 0 && c.Pos.Line() == l {
 			c.Pos = c.Pos.WithIsStmt()
 		}
 	}

 	// move all of b's values to c.
 	for _, v := range b.Values {
 		v.Block = c
 	}
 	// Use whichever value slice is larger, in the hopes of avoiding growth.
 	// However, take care to avoid c.Values pointing to b.valstorage.
 	// See golang.org/issue/18602.
 	// It's important to keep the elements in the same order; maintenance of
 	// debugging information depends on the order of *Values in Blocks.
 	// This can also cause changes in the order (which may affect other
 	// optimizations and possibly compiler output) for 32-vs-64 bit compilation
 	// platforms (word size affects allocation bucket size affects slice capacity).
 	if cap(c.Values) >= cap(b.Values) || len(b.Values) <= len(b.valstorage) {
 		bl := len(b.Values)
 		cl := len(c.Values)
 		var t []*Value // construct t = b.Values followed-by c.Values, but with attention to allocation.
 		if cap(c.Values) < bl+cl {
 			// reallocate
 			t = make([]*Value, bl+cl)
 		} else {
 			// in place.
 			t = c.Values[0 : bl+cl]
 		}
 		copy(t[bl:], c.Values) // possibly in-place
 		c.Values = t
 		copy(c.Values, b.Values)
 	} else {
 		c.Values = append(b.Values, c.Values...)
 	}

 	// replace b->c edge with preds(b) -> c
 	c.predstorage[0] = Edge{}
 	if len(b.Preds) > len(b.predstorage) {
 		c.Preds = b.Preds
 	} else {
 		c.Preds = append(c.predstorage[:0], b.Preds...)
 	}
 	for i, e := range c.Preds {
 		p := e.b
 		p.Succs[e.i] = Edge{c, i}
 	}
 	f := b.Func
 	if f.Entry == b {
 		f.Entry = c
 	}

 	// trash b, just in case
 	b.Kind = BlockInvalid
 	b.Values = nil
 	b.Preds = nil
 	b.Succs = nil
 	return true
 }
	// Copyright 2015 The Go Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style
	// license that can be found in the LICENSE file.

	package ssa

	import (
	"cmd/internal/src"
	)

	// fuseEarly runs fuse(f, fuseTypePlain\|fuseTypeIntInRange).
	func fuseEarly(f *Func) { fuse(f, fuseTypePlain\|fuseTypeIntInRange) }

	// fuseLate runs fuse(f, fuseTypePlain\|fuseTypeIf).
	func fuseLate(f *Func) { fuse(f, fuseTypePlain\|fuseTypeIf) }

	type fuseType uint8

	const (
	fuseTypePlain fuseType = 1 << iota
	fuseTypeIf
	fuseTypeIntInRange
	fuseTypeShortCircuit
	)

	// fuse simplifies control flow by joining basic blocks.
	func fuse(f *Func, typ fuseType) {
	for changed := true; changed; {
	changed = false
	// Fuse from end to beginning, to avoid quadratic behavior in fuseBlockPlain. See issue 13554.
	for i := len(f.Blocks) - 1; i >= 0; i-- {
	b := f.Blocks[i]
	if typ&fuseTypeIf != 0 {
	changed = fuseBlockIf(b) \|\| changed
	}
	if typ&fuseTypeIntInRange != 0 {
	changed = fuseIntegerComparisons(b) \|\| changed
	}
	if typ&fuseTypePlain != 0 {
	changed = fuseBlockPlain(b) \|\| changed
	}
	if typ&fuseTypeShortCircuit != 0 {
	changed = shortcircuitBlock(b) \|\| changed
	}
	}
	if changed {
	f.invalidateCFG()
	}
	}
	}

	// fuseBlockIf handles the following cases where s0 and s1 are empty blocks.
	//
	// b b b b
	// / \ \| \ / \| \| \|
	// s0 s1 \| s1 s0 \| \| \|
	// \ / \| / \ \| \| \|
	// ss ss ss ss
	//
	// If all Phi ops in ss have identical variables for slots corresponding to
	// s0, s1 and b then the branch can be dropped.
	// This optimization often comes up in switch statements with multiple
	// expressions in a case clause:
	// switch n {
	// case 1,2,3: return 4
	// }
	// TODO: If ss doesn't contain any OpPhis, are s0 and s1 dead code anyway.
	func fuseBlockIf(b *Block) bool {
	if b.Kind != BlockIf {
	return false
	}

	var ss0, ss1 *Block
	s0 := b.Succs[0].b
	i0 := b.Succs[0].i
	if s0.Kind != BlockPlain \|\| len(s0.Preds) != 1 \|\| !isEmpty(s0) {
	s0, ss0 = b, s0
	} else {
	ss0 = s0.Succs[0].b
	i0 = s0.Succs[0].i
	}
	s1 := b.Succs[1].b
	i1 := b.Succs[1].i
	if s1.Kind != BlockPlain \|\| len(s1.Preds) != 1 \|\| !isEmpty(s1) {
	s1, ss1 = b, s1
	} else {
	ss1 = s1.Succs[0].b
	i1 = s1.Succs[0].i
	}

	if ss0 != ss1 {
	return false
	}
	ss := ss0

	// s0 and s1 are equal with b if the corresponding block is missing
	// (2nd, 3rd and 4th case in the figure).

	for _, v := range ss.Values {
	if v.Op == OpPhi && v.Uses > 0 && v.Args[i0] != v.Args[i1] {
	return false
	}
	}

	// Now we have two of following b->ss, b->s0->ss and b->s1->ss,
	// with s0 and s1 empty if exist.
	// We can replace it with b->ss without if all OpPhis in ss
	// have identical predecessors (verified above).
	// No critical edge is introduced because b will have one successor.
	if s0 != b && s1 != b {
	// Replace edge b->s0->ss with b->ss.
	// We need to keep a slot for Phis corresponding to b.
	b.Succs[0] = Edge{ss, i0}
	ss.Preds[i0] = Edge{b, 0}
	b.removeEdge(1)
	s1.removeEdge(0)
	} else if s0 != b {
	b.removeEdge(0)
	s0.removeEdge(0)
	} else if s1 != b {
	b.removeEdge(1)
	s1.removeEdge(0)
	} else {
	b.removeEdge(1)
	}
	b.Kind = BlockPlain
	b.Likely = BranchUnknown
	b.ResetControls()

	// Trash the empty blocks s0 and s1.
	blocks := [...]*Block{s0, s1}
	for _, s := range &blocks {
	if s == b {
	continue
	}
	// Move any (dead) values in s0 or s1 to b,
	// where they will be eliminated by the next deadcode pass.
	for _, v := range s.Values {
	v.Block = b
	}
	b.Values = append(b.Values, s.Values...)
	// Clear s.
	s.Kind = BlockInvalid
	s.Values = nil
	s.Succs = nil
	s.Preds = nil
	}
	return true
	}

	// isEmpty reports whether b contains any live values.
	// There may be false positives.
	func isEmpty(b *Block) bool {
	for _, v := range b.Values {
	if v.Uses > 0 \|\| v.Op.IsCall() \|\| v.Op.HasSideEffects() \|\| v.Type.IsVoid() {
	return false
	}
	}
	return true
	}

	func fuseBlockPlain(b *Block) bool {
	if b.Kind != BlockPlain {
	return false
	}

	c := b.Succs[0].b
	if len(c.Preds) != 1 {
	return false
	}

	// If a block happened to end in a statement marker,
	// try to preserve it.
	if b.Pos.IsStmt() == src.PosIsStmt {
	l := b.Pos.Line()
	for _, v := range c.Values {
	if v.Pos.IsStmt() == src.PosNotStmt {
	continue
	}
	if l == v.Pos.Line() {
	v.Pos = v.Pos.WithIsStmt()
	l = 0
	break
	}
	}
	if l != 0 && c.Pos.Line() == l {
	c.Pos = c.Pos.WithIsStmt()
	}
	}

	// move all of b's values to c.
	for _, v := range b.Values {
	v.Block = c
	}
	// Use whichever value slice is larger, in the hopes of avoiding growth.
	// However, take care to avoid c.Values pointing to b.valstorage.
	// See golang.org/issue/18602.
	// It's important to keep the elements in the same order; maintenance of
	// debugging information depends on the order of *Values in Blocks.
	// This can also cause changes in the order (which may affect other
	// optimizations and possibly compiler output) for 32-vs-64 bit compilation
	// platforms (word size affects allocation bucket size affects slice capacity).
	if cap(c.Values) >= cap(b.Values) \|\| len(b.Values) <= len(b.valstorage) {
	bl := len(b.Values)
	cl := len(c.Values)
	var t []*Value // construct t = b.Values followed-by c.Values, but with attention to allocation.
	if cap(c.Values) < bl+cl {
	// reallocate
	t = make([]*Value, bl+cl)
	} else {
	// in place.
	t = c.Values[0 : bl+cl]
	}
	copy(t[bl:], c.Values) // possibly in-place
	c.Values = t
	copy(c.Values, b.Values)
	} else {
	c.Values = append(b.Values, c.Values...)
	}

	// replace b->c edge with preds(b) -> c
	c.predstorage[0] = Edge{}
	if len(b.Preds) > len(b.predstorage) {
	c.Preds = b.Preds
	} else {
	c.Preds = append(c.predstorage[:0], b.Preds...)
	}
	for i, e := range c.Preds {
	p := e.b
	p.Succs[e.i] = Edge{c, i}
	}
	f := b.Func
	if f.Entry == b {
	f.Entry = c
	}

	// trash b, just in case
	b.Kind = BlockInvalid
	b.Values = nil
	b.Preds = nil
	b.Succs = nil
	return true
	}